script/process-json-numbers.c - third_party/wuffs - Git at Google

 // Copyright 2020 The Wuffs Authors.
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //    https://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.

 // ----------------

 // process-json-numbers.c processes all the numbers in the JSON-formatted data
 // read from stdin. It succeeds (with exit code 0) if the input is valid JSON
 // and all of the numbers within were processed without error.
 //
 // Without further flags, processing is a no-op and the program only verifies
 // the JSON structure.
 //
 // Pass -e (--emit-number-str) to emit each number (as a string) on its own
 // line.
 //
 // Pass -p (--parse-number-f64) to call wuffs_base__parse_number_f64 on each
 // number. Timing this program with and without this flag gives a rough measure
 // of how much time is spent solely in wuffs_base__parse_number_f64.
 //
 // Pass -r (--render-number-f64) to call wuffs_base__render_number_f64 (with
 // WUFFS_BASE__RENDER_NUMBER_FXX__JUST_ENOUGH_PRECISION) on each number. Timing
 // this program with and without this flag gives a rough measure of how much
 // time is spent solely in wuffs_base__render_number_f64.
 //
 // The -r flag is ignored unless -p is also passed.
 //
 // This program's purpose is to benchmark the wuffs_base__etc_f64 functions.
 // It's not about JSON per se, but JSON files are a source of realistic
 // floating point numbers.

 #include <inttypes.h>
 #include <stdio.h>
 #include <string.h>
 #include <unistd.h>

 // Wuffs ships as a "single file C library" or "header file library" as per
 // https://github.com/nothings/stb/blob/master/docs/stb_howto.txt
 //
 // To use that single file as a "foo.c"-like implementation, instead of a
 // "foo.h"-like header, #define WUFFS_IMPLEMENTATION before #include'ing or
 // compiling it.
 #define WUFFS_IMPLEMENTATION

 // Defining the WUFFS_CONFIG__STATIC_FUNCTIONS macro is optional, but when
 // combined with WUFFS_IMPLEMENTATION, it demonstrates making all of Wuffs'
 // functions have static storage.
 //
 // This can help the compiler ignore or discard unused code, which can produce
 // faster compiles and smaller binaries. Other motivations are discussed in the
 // "ALLOW STATIC IMPLEMENTATION" section of
 // https://raw.githubusercontent.com/nothings/stb/master/docs/stb_howto.txt
 #define WUFFS_CONFIG__STATIC_FUNCTIONS

 // Defining the WUFFS_CONFIG__MODULE* macros are optional, but it lets users of
 // release/c/etc.c choose which parts of Wuffs to build. That file contains the
 // entire Wuffs standard library, implementing a variety of codecs and file
 // formats. Without this macro definition, an optimizing compiler or linker may
 // very well discard Wuffs code for unused codecs, but listing the Wuffs
 // modules we use makes that process explicit. Preprocessing means that such
 // code simply isn't compiled.
 #define WUFFS_CONFIG__MODULES
 #define WUFFS_CONFIG__MODULE__BASE
 #define WUFFS_CONFIG__MODULE__JSON

 // If building this program in an environment that doesn't easily accommodate
 // relative includes, you can use the script/inline-c-relative-includes.go
 // program to generate a stand-alone C file.
 #include "../release/c/wuffs-unsupported-snapshot.c"

 // Uncomment this to use the github.com/lemire/fast_double_parser library. This
 // header-only library is C++, not C.
 // #define USE_LEMIRE_FAST_DOUBLE_PARSER

 #ifdef USE_LEMIRE_FAST_DOUBLE_PARSER
 #include "/the/path/to/fast_double_parser/include/fast_double_parser.h"
 #endif

 // Wuffs allows either statically or dynamically allocated work buffers. This
 // program exercises static allocation.
 #define WORK_BUFFER_ARRAY_SIZE \
   WUFFS_JSON__DECODER_WORKBUF_LEN_MAX_INCL_WORST_CASE
 #if WORK_BUFFER_ARRAY_SIZE > 0
 uint8_t g_work_buffer_array[WORK_BUFFER_ARRAY_SIZE];
 #else
 // Not all C/C++ compilers support 0-length arrays.
 uint8_t g_work_buffer_array[1];
 #endif

 #ifndef SRC_BUFFER_ARRAY_SIZE
 #define SRC_BUFFER_ARRAY_SIZE (64 * 1024 * 1024)
 #endif
 #ifndef TOKEN_BUFFER_ARRAY_SIZE
 #define TOKEN_BUFFER_ARRAY_SIZE (128 * 1024)
 #endif

 uint8_t g_src_buffer_array[SRC_BUFFER_ARRAY_SIZE];
 wuffs_base__token g_tok_buffer_array[TOKEN_BUFFER_ARRAY_SIZE];

 wuffs_base__io_buffer g_src;
 wuffs_base__token_buffer g_tok;

 wuffs_json__decoder g_dec;

 #define TRY(error_msg)         \
   do {                         \
     const char* z = error_msg; \
     if (z) {                   \
       return z;                \
     }                          \
   } while (false)

 // ignore_return_value suppresses errors from -Wall -Werror.
 static void  //
 ignore_return_value(int ignored) {}

 const char*  //
 read_src() {
   if (g_src.meta.closed) {
     return "main: internal error: read requested on a closed source";
   }
   wuffs_base__io_buffer__compact(&g_src);
   if (g_src.meta.wi >= g_src.data.len) {
     return "main: g_src buffer is full";
   }
   size_t n = fread(g_src.data.ptr + g_src.meta.wi, sizeof(uint8_t),
                    g_src.data.len - g_src.meta.wi, stdin);
   g_src.meta.wi += n;
   g_src.meta.closed = feof(stdin);
   if ((n == 0) && !g_src.meta.closed) {
     return "main: read error";
   }
   return NULL;
 }

 // ----

 struct {
   int remaining_argc;
   char** remaining_argv;

   bool emit_number_str;
   bool parse_number_f64;
   bool render_number_f64;
 } g_flags = {0};

 const char*  //
 parse_flags(int argc, char** argv) {
   int c = (argc > 0) ? 1 : 0;  // Skip argv[0], the program name.
   for (; c < argc; c++) {
     char* arg = argv[c];
     if (*arg++ != '-') {
       break;
     }

     // A double-dash "--foo" is equivalent to a single-dash "-foo". As special
     // cases, a bare "-" is not a flag (some programs may interpret it as
     // stdin) and a bare "--" means to stop parsing flags.
     if (*arg == '\x00') {
       break;
     } else if (*arg == '-') {
       arg++;
       if (*arg == '\x00') {
         c++;
         break;
       }
     }

     if (!strcmp(arg, "e") || !strcmp(arg, "emit-number-str")) {
       g_flags.emit_number_str = true;
       continue;
     }
     if (!strcmp(arg, "p") || !strcmp(arg, "parse-number-f64")) {
       g_flags.parse_number_f64 = true;
       continue;
     }
     if (!strcmp(arg, "r") || !strcmp(arg, "render-number-f64")) {
       g_flags.render_number_f64 = true;
       continue;
     }

     return "main: unrecognized flag argument";
   }

   g_flags.remaining_argc = argc - c;
   g_flags.remaining_argv = argv + c;
   return NULL;
 }

 const char*  //
 main1(int argc, char** argv) {
   TRY(parse_flags(argc, argv));
   if (g_flags.remaining_argc > 0) {
     return "main: bad argument: use \"program < input\", not \"program input\"";
   }

   uint8_t new_line[1];
   new_line[0] = '\n';

   g_src = wuffs_base__make_io_buffer(
       wuffs_base__make_slice_u8(g_src_buffer_array, SRC_BUFFER_ARRAY_SIZE),
       wuffs_base__empty_io_buffer_meta());

   g_tok = wuffs_base__make_token_buffer(
       wuffs_base__make_slice_token(g_tok_buffer_array, TOKEN_BUFFER_ARRAY_SIZE),
       wuffs_base__empty_token_buffer_meta());

   wuffs_base__status init_status = wuffs_json__decoder__initialize(
       &g_dec, sizeof__wuffs_json__decoder(), WUFFS_VERSION, 0);
   if (!wuffs_base__status__is_ok(&init_status)) {
     return wuffs_base__status__message(&init_status);
   }

   uint64_t pos = 0;
   while (true) {
     wuffs_base__status status = wuffs_json__decoder__decode_tokens(
         &g_dec, &g_tok, &g_src,
         wuffs_base__make_slice_u8(g_work_buffer_array, WORK_BUFFER_ARRAY_SIZE));

     while (g_tok.meta.ri < g_tok.meta.wi) {
       wuffs_base__token* t = &g_tok.data.ptr[g_tok.meta.ri++];
       uint64_t len = wuffs_base__token__length(t);

       if (wuffs_base__token__value_base_category(t) ==
           WUFFS_BASE__TOKEN__VBC__NUMBER) {
         uint64_t buf_pos = pos - g_src.meta.pos;
         uint64_t buf_len = g_src.data.len;
         if ((buf_len < buf_pos) || ((buf_len - buf_pos) < len)) {
           return "main: internal error: inconsistent token position/length";
         }

         if (g_flags.emit_number_str) {
           const int stdout_fd = 1;
           ignore_return_value(write(stdout_fd, &g_src.data.ptr[buf_pos], len));
           ignore_return_value(write(stdout_fd, &new_line[0], 1));
         }

         if (g_flags.parse_number_f64) {
           wuffs_base__result_f64 r;

 #ifdef USE_LEMIRE_FAST_DOUBLE_PARSER
           // Wuffs (and its JSON parser) works with slices (pointer-length
           // pairs) but fast_double_parser works with NUL-terminated strings.
           char buf[1024];
           if (len > 1023) {
             return "main: number-as-string is too long";
           }
           memcpy(&buf[0], &g_src.data.ptr[buf_pos], len);
           buf[len] = 0;
           if (!fast_double_parser::decimal_separator_dot::parse_number(
                   &buf[0], &r.value)) {
             return "main: could not parse number";
           }
           r.status = wuffs_base__make_status(NULL);
 #else
           r = wuffs_base__parse_number_f64(
               wuffs_base__make_slice_u8(&g_src.data.ptr[buf_pos], len),
               WUFFS_BASE__PARSE_NUMBER_XXX__DEFAULT_OPTIONS);
           if (!wuffs_base__status__is_ok(&r.status)) {
             return wuffs_base__status__message(&r.status);
           }
 #endif

           if (g_flags.render_number_f64) {
             uint8_t render_buffer[2048];
             size_t n = wuffs_base__render_number_f64(
                 wuffs_base__make_slice_u8(&render_buffer[0], 2048), r.value, 0,
                 WUFFS_BASE__RENDER_NUMBER_FXX__JUST_ENOUGH_PRECISION);
             if (n == 0) {
               return "main: internal error: couldn't render_number_f64";
             }
           }
         }
       }

       pos += len;
       if (0 > ((int64_t)pos)) {
         return "main: input is too long";
       }
     }

     if (status.repr == NULL) {
       return NULL;
     } else if (status.repr == wuffs_base__suspension__short_read) {
       TRY(read_src());
     } else if (status.repr == wuffs_base__suspension__short_write) {
       wuffs_base__token_buffer__compact(&g_tok);
     } else {
       return wuffs_base__status__message(&status);
     }
   }
 }

 // ----

 int  //
 compute_exit_code(const char* status_msg) {
   if (!status_msg) {
     return 0;
   }
   size_t n = strnlen(status_msg, 2047);
   if (n >= 2047) {
     status_msg = "main: internal error: error message is too long";
     n = strnlen(status_msg, 2047);
   }
   fprintf(stderr, "%s\n", status_msg);
   // Return an exit code of 1 for regular (foreseen) errors, e.g. badly
   // formatted or unsupported input.
   //
   // Return an exit code of 2 for internal (exceptional) errors, e.g. defensive
   // run-time checks found that an internal invariant did not hold.
   //
   // Automated testing, including badly formatted inputs, can therefore
   // discriminate between expected failure (exit code 1) and unexpected failure
   // (other non-zero exit codes). Specifically, exit code 2 for internal
   // invariant violation, exit code 139 (which is 128 + SIGSEGV on x86_64
   // linux) for a segmentation fault (e.g. null pointer dereference).
   return strstr(status_msg, "internal error:") ? 2 : 1;
 }

 int  //
 main(int argc, char** argv) {
   const char* z = main1(argc, argv);
   int exit_code = compute_exit_code(z);
   return exit_code;
 }
	// Copyright 2020 The Wuffs Authors.
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// https://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.

	// ----------------

	// process-json-numbers.c processes all the numbers in the JSON-formatted data
	// read from stdin. It succeeds (with exit code 0) if the input is valid JSON
	// and all of the numbers within were processed without error.
	//
	// Without further flags, processing is a no-op and the program only verifies
	// the JSON structure.
	//
	// Pass -e (--emit-number-str) to emit each number (as a string) on its own
	// line.
	//
	// Pass -p (--parse-number-f64) to call wuffs_base__parse_number_f64 on each
	// number. Timing this program with and without this flag gives a rough measure
	// of how much time is spent solely in wuffs_base__parse_number_f64.
	//
	// Pass -r (--render-number-f64) to call wuffs_base__render_number_f64 (with
	// WUFFS_BASE__RENDER_NUMBER_FXX__JUST_ENOUGH_PRECISION) on each number. Timing
	// this program with and without this flag gives a rough measure of how much
	// time is spent solely in wuffs_base__render_number_f64.
	//
	// The -r flag is ignored unless -p is also passed.
	//
	// This program's purpose is to benchmark the wuffs_base__etc_f64 functions.
	// It's not about JSON per se, but JSON files are a source of realistic
	// floating point numbers.

	#include <inttypes.h>
	#include <stdio.h>
	#include <string.h>
	#include <unistd.h>

	// Wuffs ships as a "single file C library" or "header file library" as per
	// https://github.com/nothings/stb/blob/master/docs/stb_howto.txt
	//
	// To use that single file as a "foo.c"-like implementation, instead of a
	// "foo.h"-like header, #define WUFFS_IMPLEMENTATION before #include'ing or
	// compiling it.
	#define WUFFS_IMPLEMENTATION

	// Defining the WUFFS_CONFIG__STATIC_FUNCTIONS macro is optional, but when
	// combined with WUFFS_IMPLEMENTATION, it demonstrates making all of Wuffs'
	// functions have static storage.
	//
	// This can help the compiler ignore or discard unused code, which can produce
	// faster compiles and smaller binaries. Other motivations are discussed in the
	// "ALLOW STATIC IMPLEMENTATION" section of
	// https://raw.githubusercontent.com/nothings/stb/master/docs/stb_howto.txt
	#define WUFFS_CONFIG__STATIC_FUNCTIONS

	// Defining the WUFFS_CONFIG__MODULE* macros are optional, but it lets users of
	// release/c/etc.c choose which parts of Wuffs to build. That file contains the
	// entire Wuffs standard library, implementing a variety of codecs and file
	// formats. Without this macro definition, an optimizing compiler or linker may
	// very well discard Wuffs code for unused codecs, but listing the Wuffs
	// modules we use makes that process explicit. Preprocessing means that such
	// code simply isn't compiled.
	#define WUFFS_CONFIG__MODULES
	#define WUFFS_CONFIG__MODULE__BASE
	#define WUFFS_CONFIG__MODULE__JSON

	// If building this program in an environment that doesn't easily accommodate
	// relative includes, you can use the script/inline-c-relative-includes.go
	// program to generate a stand-alone C file.
	#include "../release/c/wuffs-unsupported-snapshot.c"

	// Uncomment this to use the github.com/lemire/fast_double_parser library. This
	// header-only library is C++, not C.
	// #define USE_LEMIRE_FAST_DOUBLE_PARSER

	#ifdef USE_LEMIRE_FAST_DOUBLE_PARSER
	#include "/the/path/to/fast_double_parser/include/fast_double_parser.h"
	#endif

	// Wuffs allows either statically or dynamically allocated work buffers. This
	// program exercises static allocation.
	#define WORK_BUFFER_ARRAY_SIZE \
	WUFFS_JSON__DECODER_WORKBUF_LEN_MAX_INCL_WORST_CASE
	#if WORK_BUFFER_ARRAY_SIZE > 0
	uint8_t g_work_buffer_array[WORK_BUFFER_ARRAY_SIZE];
	#else
	// Not all C/C++ compilers support 0-length arrays.
	uint8_t g_work_buffer_array[1];
	#endif

	#ifndef SRC_BUFFER_ARRAY_SIZE
	#define SRC_BUFFER_ARRAY_SIZE (64 * 1024 * 1024)
	#endif
	#ifndef TOKEN_BUFFER_ARRAY_SIZE
	#define TOKEN_BUFFER_ARRAY_SIZE (128 * 1024)
	#endif

	uint8_t g_src_buffer_array[SRC_BUFFER_ARRAY_SIZE];
	wuffs_base__token g_tok_buffer_array[TOKEN_BUFFER_ARRAY_SIZE];

	wuffs_base__io_buffer g_src;
	wuffs_base__token_buffer g_tok;

	wuffs_json__decoder g_dec;

	#define TRY(error_msg) \
	do { \
	const char* z = error_msg; \
	if (z) { \
	return z; \
	} \
	} while (false)

	// ignore_return_value suppresses errors from -Wall -Werror.
	static void //
	ignore_return_value(int ignored) {}

	const char* //
	read_src() {
	if (g_src.meta.closed) {
	return "main: internal error: read requested on a closed source";
	}
	wuffs_base__io_buffer__compact(&g_src);
	if (g_src.meta.wi >= g_src.data.len) {
	return "main: g_src buffer is full";
	}
	size_t n = fread(g_src.data.ptr + g_src.meta.wi, sizeof(uint8_t),
	g_src.data.len - g_src.meta.wi, stdin);
	g_src.meta.wi += n;
	g_src.meta.closed = feof(stdin);
	if ((n == 0) && !g_src.meta.closed) {
	return "main: read error";
	}
	return NULL;
	}

	// ----

	struct {
	int remaining_argc;
	char** remaining_argv;

	bool emit_number_str;
	bool parse_number_f64;
	bool render_number_f64;
	} g_flags = {0};

	const char* //
	parse_flags(int argc, char** argv) {
	int c = (argc > 0) ? 1 : 0; // Skip argv[0], the program name.
	for (; c < argc; c++) {
	char* arg = argv[c];
	if (*arg++ != '-') {
	break;
	}

	// A double-dash "--foo" is equivalent to a single-dash "-foo". As special
	// cases, a bare "-" is not a flag (some programs may interpret it as
	// stdin) and a bare "--" means to stop parsing flags.
	if (*arg == '\x00') {
	break;
	} else if (*arg == '-') {
	arg++;
	if (*arg == '\x00') {
	c++;
	break;
	}
	}

	if (!strcmp(arg, "e") \|\| !strcmp(arg, "emit-number-str")) {
	g_flags.emit_number_str = true;
	continue;
	}
	if (!strcmp(arg, "p") \|\| !strcmp(arg, "parse-number-f64")) {
	g_flags.parse_number_f64 = true;
	continue;
	}
	if (!strcmp(arg, "r") \|\| !strcmp(arg, "render-number-f64")) {
	g_flags.render_number_f64 = true;
	continue;
	}

	return "main: unrecognized flag argument";
	}

	g_flags.remaining_argc = argc - c;
	g_flags.remaining_argv = argv + c;
	return NULL;
	}

	const char* //
	main1(int argc, char** argv) {
	TRY(parse_flags(argc, argv));
	if (g_flags.remaining_argc > 0) {
	return "main: bad argument: use \"program < input\", not \"program input\"";
	}

	uint8_t new_line[1];
	new_line[0] = '\n';

	g_src = wuffs_base__make_io_buffer(
	wuffs_base__make_slice_u8(g_src_buffer_array, SRC_BUFFER_ARRAY_SIZE),
	wuffs_base__empty_io_buffer_meta());

	g_tok = wuffs_base__make_token_buffer(
	wuffs_base__make_slice_token(g_tok_buffer_array, TOKEN_BUFFER_ARRAY_SIZE),
	wuffs_base__empty_token_buffer_meta());

	wuffs_base__status init_status = wuffs_json__decoder__initialize(
	&g_dec, sizeof__wuffs_json__decoder(), WUFFS_VERSION, 0);
	if (!wuffs_base__status__is_ok(&init_status)) {
	return wuffs_base__status__message(&init_status);
	}

	uint64_t pos = 0;
	while (true) {
	wuffs_base__status status = wuffs_json__decoder__decode_tokens(
	&g_dec, &g_tok, &g_src,
	wuffs_base__make_slice_u8(g_work_buffer_array, WORK_BUFFER_ARRAY_SIZE));

	while (g_tok.meta.ri < g_tok.meta.wi) {
	wuffs_base__token* t = &g_tok.data.ptr[g_tok.meta.ri++];
	uint64_t len = wuffs_base__token__length(t);

	if (wuffs_base__token__value_base_category(t) ==
	WUFFS_BASE__TOKEN__VBC__NUMBER) {
	uint64_t buf_pos = pos - g_src.meta.pos;
	uint64_t buf_len = g_src.data.len;
	if ((buf_len < buf_pos) \|\| ((buf_len - buf_pos) < len)) {
	return "main: internal error: inconsistent token position/length";
	}

	if (g_flags.emit_number_str) {
	const int stdout_fd = 1;
	ignore_return_value(write(stdout_fd, &g_src.data.ptr[buf_pos], len));
	ignore_return_value(write(stdout_fd, &new_line[0], 1));
	}

	if (g_flags.parse_number_f64) {
	wuffs_base__result_f64 r;

	#ifdef USE_LEMIRE_FAST_DOUBLE_PARSER
	// Wuffs (and its JSON parser) works with slices (pointer-length
	// pairs) but fast_double_parser works with NUL-terminated strings.
	char buf[1024];
	if (len > 1023) {
	return "main: number-as-string is too long";
	}
	memcpy(&buf[0], &g_src.data.ptr[buf_pos], len);
	buf[len] = 0;
	if (!fast_double_parser::decimal_separator_dot::parse_number(
	&buf[0], &r.value)) {
	return "main: could not parse number";
	}
	r.status = wuffs_base__make_status(NULL);
	#else
	r = wuffs_base__parse_number_f64(
	wuffs_base__make_slice_u8(&g_src.data.ptr[buf_pos], len),
	WUFFS_BASE__PARSE_NUMBER_XXX__DEFAULT_OPTIONS);
	if (!wuffs_base__status__is_ok(&r.status)) {
	return wuffs_base__status__message(&r.status);
	}
	#endif

	if (g_flags.render_number_f64) {
	uint8_t render_buffer[2048];
	size_t n = wuffs_base__render_number_f64(
	wuffs_base__make_slice_u8(&render_buffer[0], 2048), r.value, 0,
	WUFFS_BASE__RENDER_NUMBER_FXX__JUST_ENOUGH_PRECISION);
	if (n == 0) {
	return "main: internal error: couldn't render_number_f64";
	}
	}
	}
	}

	pos += len;
	if (0 > ((int64_t)pos)) {
	return "main: input is too long";
	}
	}

	if (status.repr == NULL) {
	return NULL;
	} else if (status.repr == wuffs_base__suspension__short_read) {
	TRY(read_src());
	} else if (status.repr == wuffs_base__suspension__short_write) {
	wuffs_base__token_buffer__compact(&g_tok);
	} else {
	return wuffs_base__status__message(&status);
	}
	}
	}

	// ----

	int //
	compute_exit_code(const char* status_msg) {
	if (!status_msg) {
	return 0;
	}
	size_t n = strnlen(status_msg, 2047);
	if (n >= 2047) {
	status_msg = "main: internal error: error message is too long";
	n = strnlen(status_msg, 2047);
	}
	fprintf(stderr, "%s\n", status_msg);
	// Return an exit code of 1 for regular (foreseen) errors, e.g. badly
	// formatted or unsupported input.
	//
	// Return an exit code of 2 for internal (exceptional) errors, e.g. defensive
	// run-time checks found that an internal invariant did not hold.
	//
	// Automated testing, including badly formatted inputs, can therefore
	// discriminate between expected failure (exit code 1) and unexpected failure
	// (other non-zero exit codes). Specifically, exit code 2 for internal
	// invariant violation, exit code 139 (which is 128 + SIGSEGV on x86_64
	// linux) for a segmentation fault (e.g. null pointer dereference).
	return strstr(status_msg, "internal error:") ? 2 : 1;
	}

	int //
	main(int argc, char** argv) {
	const char* z = main1(argc, argv);
	int exit_code = compute_exit_code(z);
	return exit_code;
	}